CORPUSCLES OF LIGHT

The theory of EM-wave propagation is a relatively recent addition to the storehouse of physics knowledge. Isaac Newton, the seventeenth-century English physicist and mathematician known for his theory of gravitation and his role in the invention of calculus, believed that visible light consists of submicroscopic particles. To the casual observer, visible light travels in straight lines through air or free space. Shadows are cast in such a way as to suggest that there are no exceptions to this rule, at least in a vacuum. Today scientists know that light behaves, in some ways, like a barrage of bullets. Particles of EM energy, called photons, have momentum, and they exert measurable pressure on objects they strike. The energy in a beam of light can be broken down into packets of a certain minimum size but no smaller.
However, one need not search hard to find complications with Newton’s corpuscular theory of the nature of light. At a boundary between air and water, photons do inexplicable things. Ask any child who has ever stuck a fishing pole into a lake or who has looked into the deep end of a swimming pool and seen 4 m of water look like 1 m. Photons change direction abruptly when they pass at a sharp angle from water to air or vice versa (Fig. 1), but there is no apparent force to give them a sideways push. When light passes through a glass prism, things get stranger still; not only are light beams bent by the glass, but the extent to which they are bent depends on the color!

Fig. 1. If light rays consist of particles, what pushes them sideways at the water surface?

مواضيع ذات صلة

انتشار الضوء في خطوط مستقيمة

القياس الضوئي

انعكاس الضوء عن سطح كرى – المرايا الكرية

انعكاس الضوء عند سطح مستوى - المرآة المستوية

The momentum of light

Polarization of scattered light

The electric vector of light

Scattering of light

Reflection and refraction

Light

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